• Remote-control skillful rescue robot demonstrated

    Researchers have developed a prototype construction robot for disaster relief situations. This prototype has drastically improved operability and mobility compared to conventional construction machines.

  • Seeking greater accuracy in predicting storm strength

    Fully developed tropical cyclones — variously called hurricanes, typhoons or cyclones, depending on their region — can grow as wide as several hundred miles and sustain winds faster than 150 miles per hour. For example, Typhoon Tip (1979) had 190-mph winds and Hurricane Patricia (2015) whipped up 215-mph winds (the record). Such storms are notoriously difficult to predict, presenting a volatile meteorological cocktail that can change direction, speed, and strength, quickly and unexpectedly.

  • Helping shape safer coastal communities

    Higher dunes can help protect communities from damaging waves and surge; they can also impede natural coastal processes. Scientists need better to understand how dunes’ effectiveness in protecting developed areas will be affected by long-term coastal change, or by extreme events such as hurricanes. Coastal zone research projects will fill in some of those knowledge gaps, heling managers protect developed areas’ beach dunes, which are vital to resilient communities, ecosystems, and economies.

  • Accelerating sea level rise threatens communities, infrastructure in NY, NJ, Conn.

    Parts of the New York, New Jersey, and Connecticut metropolitan area are at risk of being permanently flooded by sea level rise. A new study details the severe threats posed to the region’s bay areas, coastal urban centers, beach communities, and airports and seaports by as little as one foot of sea level rise, a possibility as soon as the 2030s. Sea level rise already has begun to affect communities and critical infrastructure in the region, and presents tough decisions for vulnerable areas.

  • U.K. winter 2015-16 floods: One of the century’s most extreme and severe flood episodes

    A new scientific review of the winter floods of 2015-2016 confirms that the event was one of the most extreme and severe hydrological events of the last century. The new hydrological appraisal brings together both river flow and meteorological data in an analysis of the events that led to extensive river flooding in northern England, Scotland, Northern Ireland, and parts of Wales over a three-month period.

  • Climate change likely caused deadly 2016 avalanche in Tibet

    On 17 July, more than 70 million tons of ice broke off from the Aru glacier in the mountains of western Tibet and tumbled into a valley below, taking the lives of nine nomadic yak herders living there. With the deadly avalanche, it appears climate change may now be affecting a once stable region of the Tibetan Plateau, researchers have concluded, as two glaciers collapse within two months in once-stable region.

  • Warming-driven loss of soil carbon might equal U.S. emissions

    For decades scientists have speculated that rising global temperatures might alter the ability of soils to store carbon, potentially releasing huge amounts of carbon into the atmosphere and triggering runaway climate change. Yet thousands of studies worldwide have produced mixed signals on whether this storage capacity will actually decrease — or even increase — as the planet warms. It turns out scientists might have been looking in the wrong places. A new study finds that warming will drive the loss of at least 55 trillion kilograms of carbon from the soil by mid-century, or about 17 percent more than the projected emissions due to human-related activities during that period. That would be roughly the equivalent of adding to the planet another industrialized country the size of the United States.

  • U.S. to face five-fold increase in extreme downpours across parts of the country

    At century’s end, the number of summertime storms that produce extreme downpours could increase by more than 400 percent across parts of the United States — including sections of the Gulf Coast, Atlantic Coast, and the Southwest. The intensity of individual extreme rainfall events could increase by as much as 70 percent in some areas. That would mean that a storm that drops about 2 inches of rainfall today would be likely to drop nearly 3.5 inches in the future.

  • Climate change to drive stronger, smaller storms in U.S.

    The effects of climate change will likely cause smaller but stronger storms in the United States, according to a new framework for modeling storm behavior. Though storm intensity is expected to increase over today’s levels, the predicted reduction in storm size may alleviate some fears of widespread severe flooding in the future. The new approach uses new statistical methods to identify and track storm features in both observational weather data and new high-resolution climate modeling simulations.

  • USGS, DoD partner in preparing for major natural disasters

    In 2003, USGS partnered with the U.S. Department of Defense (DOD) - U.S. Northern Command (USNORTHCOM) to establish a liaison between the two organizations to facilitate science support in the event of a major natural disaster. The USGS liaison coordinates requests for science information and expertise, and general civil support and humanitarian assistance activities. This science support enables USNORTHCOM to perform critical national defense and civil support missions, as well as understand the impacts of natural disasters.

  • Is climate change responsible for increasing tornado outbreaks?

    Tornadoes and severe thunderstorms kill people and damage property every year. Estimated U.S. insured losses due to severe thunderstorms in the first half of 2016 were $8.5 billion. The largest U.S. impacts of tornadoes result from tornado outbreaks, sequences of tornadoes that occur in close succession. New research shows that the average number of tornadoes during outbreaks—large-scale weather events that can last one to three days and span huge regions—has risen since 1954. But the researchers were not sure why.

  • Better way for coastal communities to prepare for devastating storms

    As of 2010, approximately 52 percent of the United States’ population lived in vulnerable coastal watershed counties, and that number is expected to grow. Globally, almost half of the world’s population lives along or near coastal areas. Coastal communities’ ability to plan for, absorb, recover, and adapt from destructive hurricanes is becoming more urgent.

  • Record-breaking hot days ahead

    If society continues to pump greenhouse gases into the atmosphere at the current rate, Americans later this century will have to endure, on average, about fifteen daily maximum temperature records for every time that the mercury notches a record low, new research indicates. That ratio of record highs to record lows could also turn out to be much higher if the pace of emissions increases and produces even more warming.

  • How social media is energizing crisis response

    Natural disasters, such as the recent Hurricane Matthew in the Caribbean, present a huge challenge for governments, non-governmental organizations, and of course the individuals and communities affected. But studies of the effectiveness or otherwise of the responses to these disasters typically focus on official activities, producing a top-down view of what unfolded. Researchers studying the 2011 Thailand flooding disaster – the world’s fourth most severe natural disaster at that time instead looked at how individuals on the ground used social media to share information and offer support, often in areas where the official response was lacking or ineffective.

  • Satellite confirmation: San Francisco's Millennium Tower is sinking

    The Sentinel-1 satellites have shown that the Millennium Tower skyscraper in the center of San Francisco is sinking by a few centimeters a year. Studying the city is helping scientists to improve the monitoring of urban ground movements, particularly for subsidence hotspots in Europe. Completed in 2009, the 58-storey Millennium Tower has recently been showing signs of sinking and tilting. Although the cause has not been pinpointed, it is believed that the movements are connected to the supporting piles not firmly resting on bedrock.